Community

Sabine Zinn Member since: Tuesday, January 13, 2015

Dr.

Development and usage of demographic microsimulation tools and applications, in particular mate-matching and statistical modeling as well as analysis of output

mateenraj Member since: Monday, March 05, 2012

Matej Zajc Member since: Sunday, October 20, 2019 Full Member

martin matias Member since: Wednesday, May 20, 2020 Full Member

Mario Gonzalez Member since: Monday, December 11, 2017

Msc Matematicas Aplicadas

Simen Oestmo Member since: Saturday, September 21, 2013

Bachelor degree in Social Sciences - Archaeology, Master of Arts in Anthropology - Archaeology, PhD in Anthropology - Archaeology

Muhammad Indra Al Irsyad Member since: Wednesday, November 22, 2017 Full Member Reviewer

Master degree, PhD candidate

My research examines the most effective and efficient policies for renewable energy development using an approach that integrates input-output analysis, life cycle analysis, econometric, and agent-based modelling to estimate the impacts of the policies to economic, emission, extracted materials, renewable energy capacity and social acceptance.

Christian Reynolds Member since: Friday, May 20, 2016

PhD Applied Math

Christian Reynolds is a Public Health Research Fellow at the Rowett Institute of Nutrition and Health, University of Aberdeen, and an adjunct Research Fellow at the Barbara Hardy Institute for Sustainable Environments and Technologies, University of South Australia. Christian’s research examines the economic and environmental impacts of food consumption; with focus upon food waste, sustainable diets, and the political power of food in international relations.
Christian has experience in economic input-output, material flow and environmental (Life Cycle Analysis) modelling and has published peer reviewed articles on these topics.

Paul Van Liedekerke Member since: Thursday, May 31, 2018

Interested in numerical models and new conceptual ideas, applications from industry to medicine.

I focus on numerical modeling of mechanics of solid materials and cell mechanics. The models that I developed so far address granular matters, bio-fluids, cellular tissues, and individual cells.

I further develop Agent-based Models, which are methods to predict collective behavior from individual dynamics controlled by rules or differential equations. Examples: tumor growth, swarms, crowd movement.

The methods I used are Particle-based methods which offer great flexibility within physical modeling, and can operate in a large range of scales, from atomistic scales (e.g. Molecular Dynamics) to continuum approaches (e.g. Smoothed Particle Hydrodynamics).

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